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1 Kupferausfuhrland
Kupferausfuhrland
copper exporter;
• Kupferbergwerk copper mine;
• Kupfererz copper ore;
• Kupfergeld, Kupfermünze copper [coin];
• Kupfergewinnung copper extraction;
• Kupferhütte copper mill, copperworks, copper-smelting plant (works);
• Kupfermünze copper, bown (sl.);
• Kupferseide copper rayon;
• Kupfervorkommen copper deposit;
• Kupferwerk copperworks;
• Kupferwerte (Börse) copper issues, coppers. -
2 utvinning
exploitation, extraction, recoveryblyutvinning; lead recoverykopparutvinning; copper extraction, extraction of copper -
3 извлечение меди
Metallurgy: copper extraction -
4 обезмедивание
1) Engineering: decopperization2) Makarov: copper extraction, decoppering -
5 обезмеживание
Makarov: copper extraction, decoppering -
6 Kupfergewinnung
Kupfergewinnung
copper extraction -
7 kopparutvinning
copper extrection, extraction of copper -
8 медь в порошке
[lang name="Russian"]проявляющий порошок, тонер, тон-порошок — developer powder
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9 медный порошок
[lang name="Russian"]проявляющий порошок, тонер, тон-порошок — developer powder
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10 Coster, John
[br]b. c. 1647 Gloucestershire, Englandd. 13 October 1718 Bristol, England[br]English innovator in the mining, smelting and working of copper.[br]John Coster, son of an iron-forge manager in the Forest of Dean, by the age of 38 was at Bristol, where he was "chief agent and sharer therein" in the new lead-smelting methods using coal fuel. In 1685 the work, under Sir Clement Clerke, was abandoned because of patent rights claimed by Lord Grandison, who financed of earlier attempts. Clerke's business turned to the coal-fired smelting of copper under Coster, later acknowledged as responsible for the subsequent success through using an improved reverberatory furnace which separated coal fume from the ores being smelted. The new technique, applicable also to lead and tin smelting, revitalized copper production and provided a basis for new British industry in both copper and brass manufacture during the following century. Coster went on to manage a copper-smelting works, and by the 1690s was supplying Esher copper-and brass-works in Surrey from his Redbrook, Gloucestershire, works on the River Wye. In the next decade he extended his activities to Cornish copper mining, buying ore and organizing ore sales, and supplying the four major copper and brass companies which by then had become established. He also made copper goods in additional water-powered rolling and hammer mills acquired in the Bristol area. Coster was ably assisted by three sons; of these, John and Robert were mainly active in Cornwall. In 1714 the younger John, with his father, patented an "engine for drawing water out of deep mines". The eldest son, Thomas, was more involved at Redbrook, in South Wales and the Bristol area. A few years after the death of his father, Thomas became partner in the brass company of Bristol and sold them the Redbrook site. He became Member of Parliament for Bristol and, by then the only surviving son, planned a large new smelting works at White Rock, Swansea, South Wales, before his death in 1734. Partners outside the family continued the business under a new name.[br]Bibliography1714, British patent 397, with John Coster Jr.Further ReadingRhys Jenkins, 1942, "Copper works at Redbrook and Bristol", Transactions of the Bristol and Gloucestershire Archaeological Society 63.Joan Day, 1974–6, "The Costers: copper smelters and manufacturers", Transactions of the Newcomen Society 47:47–58.JD -
11 Williams, Thomas
[br]b. 13 May 1737 Cefn Coch, Anglesey, Walesd. 29 November 1802 Bath, England[br]Welsh lawyer, mine-owner and industrialist.[br]Williams was articled by his father, Owen Williams of Treffos in Anglesey, to the prominent Flintshire lawyer John Lloyd, whose daughter Catherine he is believed to have married. By 1769 Williams, lessee of the mansion and estate of Llanidan, was an able lawyer with excellent connections in Anglesey. His life changed dramatically when he agreed to act on behalf of the Lewis and Hughes families of Llysdulas, who had begun a lawsuit against Sir Nicholas Bayly of Plas Newydd concerning the ownership and mineral rights of copper mines on the western side of Parys mountain. During a prolonged period of litigation, Williams managed these mines for Margaret Lewis on behalf of Edward Hughes, who was established after a judgement in Chancery in 1776 as one of two legal proprietors, the other being Nicholas Bayly. The latter then decided to lease his portion to the London banker John Dawes, who in 1778 joined Hughes and Thomas Williams when they founded the Parys Mine Company.As the active partner in this enterprise, Williams began to establish his own smelting and fabricating works in South Wales, Lancashire and Flintshire, where coal was cheap. He soon broke the power of Associated Smelters, a combine holding the Anglesey mine owners to ransom. The low production cost of Anglesey ore gave him a great advantage over the Cornish mines and he secured very profitable contracts for the copper sheathing of naval and other vessels. After several British and French copper-bottomed ships were lost because of corrosion failure of the iron nails and bolts used to secure the sheathing, Williams introduced a process for manufacturing heavily work-hardened copper bolts and spikes which could be substituted directly for iron fixings, avoiding the corrosion difficulty. His new product was adopted by the Admiralty in 1784 and was soon used extensively in British and European dockyards.In 1785 Williams entered into partnership with Lord Uxbridge, son and heir of Nicholas Bayly, to run the Mona Mine Company at the Eastern end of Parys Mountain. This move ended much enmity and litigation and put Williams in effective control of all Anglesey copper. In the same year, Williams, with Matthew Boulton and John Wilkinson, persuaded the Cornish miners to establish a trade cooperative, the Cornish Metal Company, to market their ores. When this began to fall in 1787, Williams took over its administration, assets and stocks and until 1792 controlled the output and sale of all British copper. He became known as the "Copper King" and the output of his many producers was sold by the Copper Offices he established in London, Liverpool and Birmingham. In 1790 he became Member of Parliament for the borough of Great Marlow, and in 1792 he and Edward Hughes established the Chester and North Wales Bank, which in 1900 was absorbed by the Lloyds group.After 1792 the output of the Anglesey mines started to decline and Williams began to buy copper from all available sources. The price of copper rose and he was accused of abusing his monopoly. By this time, however, his health had begun to deteriorate and he retreated to Bath.[br]Further ReadingJ.R.Harris, 1964, The "Copper King", Liverpool University Press.ASD -
12 MacArthur, John Stewart
[br]b. December 1856 Hutchesontown, Glasgow, Scotlandd. 16 March 1920 Pollokshields, Glasgow, Scotland[br]Scottish industrial chemist who introduced the "cyanide process" for the commercial extraction of gold from its ores.[br]MacArthur served his apprenticeship in the laboratory of Tennant's Tharsis Sulphur and Copper Company in Glasgow. In 1886 he was appointed Technical Manager of the Tennant-run Cassel Gold Extracting Company. By 1888 he was advocating a treatment scheme in which gold was dissolved from crushed rock by a dilute solution of alkali cyanide and then precipitated onto finely divided zinc. During the next few years, with several assistants, he was extremely active in promoting the new gold-extraction technique in various parts of the world. In 1894 significant sums in royalty payments were received, but by 1897 the patents had been successfully contested; henceforth the Cassel Company concentrated on the production and marketing of the essential sodium cyanide reagent.MacArthur was Managing Director of the Cassel Company from 1892 to 1897; he resigned as a director in December 1905. In 1907 he created the Antimony Recovery Syndicate, and in 1911 he set up a small plant at Runcorn, Cheshire, to produce radium salts. In 1915 this radium-extraction activity was transferred to Balloch, south of Loch Lomond, where it was used until some years after his death.[br]Principal Honours and DistinctionsInstitution of Mining and Metallurgy Gold Medal 1902.Bibliography10 August 1888, jointly with R.W.Forrest and W.Forrest, British patent no. 14,174. 13 July 1889, jointly with R.W.Forrest and W. Forrest, British patent no. 10,223. 1905, "Gold extraction by cyanide: a retrospect", Journal of the Society of ChemicalIndustry (15 April):311–15.Further ReadingD.I.Harvie, 1989, "John Stewart MacArthur: pioneer gold and radium refiner", Endeavour (NS) 13(4):179–84 (draws on family documents not previously published).JKABiographical history of technology > MacArthur, John Stewart
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13 Stanley, Robert Crooks
[br]b. 1 August 1876 Little Falls, New Jersey, USAd. 12 February 1951 USA[br]American mining engineer and metallurgist, originator of Monel Metal[br]Robert, the son of Thomas and Ada (Crooks) Stanley, helped to finance his early training at the Stevens Institute of Technology, Hoboken, New Jersey, by working as a manual training instructor at Montclair High School. After graduating in mechanical engineering from Stevens in 1899, and as a mining engineer from the Columbia School of Mines in 1901, he accepted a two-year assignment from the S.S.White Dental Company to investigate platinum-bearing alluvial deposits in British Columbia. This introduced him to the International Nickel Company (Inco), which had been established on 29 March 1902 to amalgamate the major mining companies working the newly discovered cupro-nickel deposits at Sudbury, Ontario. Ambrose Monell, President of Inco, appointed Stanley as Assistant Superintendent of its American Nickel Works at Camden, near Philadelphia, in 1903. At the beginning of 1904 Stanley was General Superintendent of the Orford Refinery at Bayonne, New Jersey, where most of the output of the Sudbury mines was treated.Copper and nickel were separated there from the bessemerized matte by the celebrated "tops and bottoms" process introduced thirteen years previously by R.M.Thompson. It soon occurred to Stanley that such a separation was not invariably required and that, by reducing directly the mixed matte, he could obtain a natural cupronickel alloy which would be ductile, corrosion resistant, and no more expensive to produce than pure copper or nickel. His first experiment, on 30 December 1904, was completely successful. A railway wagon full of bessemerized matte, low in iron, was calcined to oxide, reduced to metal with carbon, and finally desulphurized with magnesium. Ingots cast from this alloy were successfully forged to bars which contained 68 per cent nickel, 23 per cent copper and about 1 per cent iron. The new alloy, originally named after Ambrose Monell, was soon renamed Monel to satisfy trademark requirements. A total of 300,000 ft2 (27,870 m2) of this white, corrosion-resistant alloy was used to roof the Pennsylvania Railway Station in New York, and it also found extensive applications in marine work and chemical plant. Stanley greatly increased the output of the Orford Refinery during the First World War, and shortly after becoming President of the company in 1922, he established a new Research and Development Division headed initially by A.J.Wadham and then by Paul D. Merica, who at the US Bureau of Standards had first elucidated the mechanism of age-hardening in alloys. In the mid- 1920s a nickel-ore body of unprecedented size was identified at levels between 2,000 and 3,000 ft (600 and 900 m) below the Frood Mine in Ontario. This property was owned partially by Inco and partially by the Mond Nickel Company. Efficient exploitation required the combined economic resources of both companies. They merged on 1 January 1929, when Mond became part of International Nickel. Stanley remained President of the new company until February 1949 and was Chairman from 1937 until his death.[br]Principal Honours and DistinctionsAmerican Society for Metals Gold Medal. Institute of Metals Platinum Medal 1948.Further ReadingF.B.Howard-White, 1963, Nickel, London: Methuen (a historical review).ASD -
14 Ercker, Lazarus
[br]b. c.1530 Annaberg, Saxony, Germanyd. 1594 Prague, Bohemia[br]German chemist and metallurgist.[br]Educated at Wittenberg University during 1547–8, Ercker obtained in 1554, through one of his wife's relatives, the post of Assayer from the Elector Augustus at Dresden. From then on he took a succession of posts in mining and metallurgy. In 1555 he was Chief Consultant and Supervisor of all matters relating to mines, but for some unknown reason was demoted to Warden of the Mint at Annaberg. In 1558 he travelled to the Tyrol to study the mines in that region, and in the same year Prince Henry of Brunswick appointed him Warden, then Master, of the Mint at Goslar. Ercker later moved to Prague where, through another of his wife's relatives, he was appointed Control Tester at Kutna Hora. It was there that he wrote his best-known book, Die Beschreibung allfürnemisten mineralischen Ertz, which drew him to the attention of the Emperor Maximilian, who made him Courier for Mining and a clerk of the Supreme Court of Bohemia. The next Emperor, Rudolf II, a noted patron of science and alchemy, promoted Ercker to Chief Inspector of Mines and ennobled him in 1586 with the title Von Schreckenfels'. His second wife managed the mint at Kutna Hora and his two sons became assayers. These appointments gained him much experience of the extraction and refining of metals. This first bore fruit in a book on assaying, Probierbüchlein, printed in 1556, followed by one on minting, Münzbuch, in 1563. His main work, Die Beschreibung, was a systematic review of the methods of obtaining, refining and testing the alloys and minerals of gold, silver, copper, antimony, mercury and lead. The preparation of acids, salts and other compounds is also covered, and his apparatus is fully described and illustrated. Although Ercker used Agricola's De re metattica as a model, his own work was securely based on his practical experience. Die Beschreibung was the first manual of analytical and metallurgical chemistry and influenced later writers such as Glauber on assaying. After the first edition in Prague came four further editions in Frankfurt-am-Main.[br]BibliographyDie Beschreibung allfürnemisten mineralischen Ertz, Prague. 1556, Probierbuchlein.1563, Munzbuch.Further ReadingP.R.Beierlein, 1955, Lazarus Ercker, Bergmann, Hüttenmann und Münzmeister im 16. Jahrhundert, Berlin (the best biography, although the chemical details are incomplete).J.R.Partington, 1961, History of Chemistry, London, Vol. II, pp. 104–7.E.V.Armstrong and H.Lukens, 1939, "Lazarus Ercker and his Probierbuch", J.Chem. Ed.16: 553–62.LRD -
15 завод
industrial enterprise, factory, mill, plant, production unit, work* * *заво́д м.1. ( предприятие) factory, works, plant, mill2. ( приведение в действие механизма) winding(-up)заво́д (часо́в) без ключа́ — stem windingзаво́д (часо́в) голо́вкой — pendant winding3. ( приспособление в механизме) winding mechanism4. ( срок действия заведённого механизма) wind5. полигр. duplication of the runавтомоби́льный заво́д — брит. motor-works; амер. automobile plantаффина́жный заво́д — (gold, silver) refineryбето́нный заво́д — concrete-mixing plantбонда́рный заво́д — barrel factoryбума́жно-целлюло́зный заво́д — wood-pulp and paper millвагонострои́тельный заво́д — carriage [wagon] worksга́зовый заво́д — gas worksзаво́д железобето́нных изде́лий — concrete product plantзерноспиртово́й заво́д — grain-alcohol distilleryка́бельный заво́д — cable worksкирпи́чный заво́д — brick works, brick yardкоже́венный заво́д — tanneryко́ксовый заво́д — coking plantкоксохими́ческий заво́д — by-product coke plantкомбико́рмовый заво́д — (animal) formula-feed plantко́нный заво́д — stud farmконсе́рвный заво́д — cannery, canning plant, canning factoryкопти́льный заво́д — smoke-houseкузовострои́тельный заво́д — coachbuilding factoryледоде́лательный заво́д — ice-making plantлесопи́льный заво́д — saw millликё́ро-во́дочный заво́д — distilleryлите́йный заво́д — foundryлокомотивострои́тельный заво́д — locomotive worksльнообраба́тывающий заво́д — flax-millмаслобо́йный заво́д — oilery, oil millмаслоде́льный заво́д — butter factoryмаслоэкстракцио́нный заво́д — oil-extraction plantмашинострои́тельный заво́д — engineering works, engineering plantмедеплави́льный заво́д — copper smelteryмеднорафиниро́вочный заво́д — copper refineryметаллообраба́тывающий заво́д — metal-working plantметаллурги́ческий заво́д — metallurgical worksмети́зный заво́д метал. — hardware plantмоло́чный заво́д — dairy factory, dairy plantмоторострои́тельный заво́д — engine worksмылова́ренный заво́д — soap works, soap plantнефтеперего́нный заво́д — oil refineryоловоплави́льный заво́д — tin smelteryо́пытный заво́д — pilot-production plantзаво́д основно́й хи́мии — heavy-chemicals plantпереде́льный заво́д — semi-integrated steelworksзаво́д перви́чной обрабо́тки льна — retteryпивова́ренный заво́д — breweryзаво́д плодо́вых со́ков — fruit-juice plantплодоовощеперераба́тывающий заво́д — fruit-and-vegetable processing plantзаво́д по́лного (технологи́ческого) ци́кла — integrated worksзаво́д по обрабо́тке ры́бы, берегово́й — shore-based fish factoryпосо́льный заво́д — salteryрафина́дный заво́д — sugar refineryрафиниро́вочный заво́д метал. — refineryрыбово́дный заво́д — fish hatchery, fish farmрыбоконсе́рвный заво́д — fish cannery, fish canning plantрыбоконсе́рвный, берегово́й заво́д — shore-based fish canneryрыбоконсе́рвный, плаву́чий заво́д — floating fish canneryса́харный заво́д ( первичной обработки сырья) — sugar-mill, sugar-houseсахарорафина́дный заво́д — sugar refineryсбо́рочный заво́д — assembly plantсвинцовоплави́льный заво́д — lead smelteryзаво́д сельскохозя́йственного машинострое́ния — farm implement works, farm equipment factoryсемяочисти́тельный заво́д — seed cleaning plantсмолоперего́нный заво́д — coal-tar processing plantзаво́д с непо́лным (технологи́ческим) ци́клом — non-integrated worksсолева́ренный заво́д — salt-making plant, saltworksсолеочисти́тельный заво́д — salt refineryсолодо́венный заво́д — malt-houseзаво́д с прока́тными цеха́ми ( без доменного и сталеплавильного цехов) — non-integrated steel worksсталеплави́льный заво́д — steel works, steel plantстанкострои́тельный заво́д — machine-tool plantстеко́льный заво́д — glass worksсудострои́тельный заво́д — ship-building yard(s)суперфосфа́тный заво́д — superphosphate plantсыромя́тный заво́д — taweryта́рный заво́д — box factoryтра́кторный заво́д — tractor works, tractor plantутилизацио́нный заво́д ( по вытопке жиров) — rendering plantзаво́д фая́нсовых изде́лий — earthenware factoryхими́ческий заво́д — chemicals plantхлопкоочисти́тельный заво́д — gin house, ginneryхозрасчё́тный заво́д — self-supporting [self-paying] factoryцеме́нтный заво́д — cement plant, cement millцинкоплави́льный заво́д — zinc smelteryчугунолите́йный заво́д — ironworksчугуноплави́льный заво́д — ironworksшрифтолите́йный заво́д полигр. — type foundry -
16 завод
1. м. factory, works, plant, mill2. м. winding3. м. winding mechanism4. м. wind5. м. полигр. duplication of the runавтомобильный завод — motor-works; automobile plant
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17 Percy, John
SUBJECT AREA: Metallurgy[br]b. 23 March 1817 Nottingham, Englandd. 19 June 1889 London, England[br]English metallurgist, first Professor of Metallurgy at the School of Mines, London.[br]After a private education, Percy went to Paris in 1834 to study medicine and to attend lectures on chemistry by Gay-Lussac and Thenard. After 1838 he studied medicine at Edinburgh, obtaining his MD in 1839. In that year he was appointed Professor of Chemistry at Queen's College, Birmingham, moving to Queen's Hospital at Birmingham in 1843. During his time at Birmingham, Percy became well known for his analysis of blast furnace slags, and was involved in the manufacture of optical glass. On 7 June 1851 Percy was appointed Metallurgical Professor and Teacher at the Museum of Practical Geology established in Jermyn Street, London, and opened in May 1851. In November of 1851, when the Museum became the Government (later Royal) School of Mines, Percy was appointed Lecturer in Metallurgy. In addition to his work at Jermyn Street, Percy lectured on metallurgy to the Advanced Class of Artillery at Woolwich from 1864 until his death, and from 1866 he was Superintendent of Ventilation at the Houses of Parliament. He served from 1861 to 1864 on the Special Committee on Iron set up to examine the performance of armour-plate in relation to its purity, composition and structure.Percy is best known for his metallurgical text books, published by John Murray. Volume I of Metallurgy, published in 1861, dealt with fuels, fireclays, copper, zinc and brass; Volume II, in 1864, dealt with iron and steel; a volume on lead appeared in 1870, followed by one on fuels and refractories in 1875, and the first volume on gold and silver in 1880. Further projected volumes on iron and steel, noble metals, and on copper, did not materialize. In 1879 Percy resigned from his School of Mines appointment in protest at the proposed move from Jermyn Street to South Kensington. The rapid growth of Percy's metallurgical collection, started in 1839, eventually forced him to move to a larger house. After his death, the collection was bought by the South Kensington (later Science) Museum. Now comprising 3,709 items, it provides a comprehensive if unselective record of nineteenth-century metallurgy, the most interesting specimens being those of the first sodium-reduced aluminium made in Britain and some of the first steel produced by Bessemer in Baxter House. Metallurgy for Percy was a technique of chemical extraction, and he has been criticized for basing his system of metallurgical instruction on this assumption. He stood strangely aloof from new processes of steel making such as that of Gilchrist and Thomas, and tended to neglect early developments in physical metallurgy, but he was the first in Britain to teach metallurgy as a discipline in its own right.[br]Principal Honours and DistinctionsFRS 1847. President, Iron and Steel Institute 1885, 1886.Bibliography1861–80, Metallurgy, 5 vols, London: John Murray.Further ReadingS.J.Cackett, 1989, "Dr Percy and his metallurgical collection", Journal of the Hist. Met. Society 23(2):92–8.RLH -
18 селективная рекуперация меди с помощью экстракции жидкими мембранами на носителях
Универсальный русско-английский словарь > селективная рекуперация меди с помощью экстракции жидкими мембранами на носителях
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19 сравнительный экономический анализ удаления меди из воды методом модифицированной лигандами усил
Универсальный русско-английский словарь > сравнительный экономический анализ удаления меди из воды методом модифицированной лигандами усил
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20 сравнительный экономический анализ удаления меди из воды методом модифицированной лигандами усилен
Универсальный русско-английский словарь > сравнительный экономический анализ удаления меди из воды методом модифицированной лигандами усилен
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